DE69726092T2 - Electrically controlled filter - Google Patents

Description

The invention relates generally on filters based on transmission line resonators and in particular to a filter arrangement in which the frequency range can be changed by means of an electrical control signal.

On transmission line resonators based filters are fundamental components in modern radios. The most common filter types are bandstops divided into frequency ranges, (band rejection filters) -band rejection filters and bandpass filters- (band-pass filter), which are used to record still frequency signals in a desired frequency band (Band-rejection) or outside suppress a specific frequency band (band pass). In addition low pass filter (low-pass filters) and high-pass filters (high-pass filters) are used. Transmission line resonators, whose resonance frequencies determine the resonance range of a filter, are common cylindrical wound conductors or windings or slots or holes in an electrically non-conductive medium, pairs of conductors made of strip conductors on a card-like substrate. Usually there are in a filter between two and about eight resonators. A filter is with the rest radio set or radio via Input terminals, output terminals and control signal connections connected.

It is in numerous applications advantageous if the filter frequency range are changed while working can by supplying an electrical signal to the filter. For example, cellular construction takes place in numerous mobile telephones the transfer and reception to and through the filter in a fairly narrow Frequency band that is on different parts of a wider frequency band and can be received in a fairly narrow frequency band range, which is why the receiver band filter, whose task it is, signals other than the desired signal to lock, must be set so that the minimum of suppression in its frequency range corresponds to the frequency of the desired signal.

Document EP-A-520 641 describes an adjustable resonator, which is the arrangement of a main resonator comprises which is arranged in the signal path of a filter and with a second Coupled resonator, which includes a switching element.

This is the state of the art no simple filter before that by means of an electrical signal changed could be that comes from a bandstop filter and into a low-pass filter arrives in such a way that the filter acts as a low pass filter the entire previous stop band passes; however, in both make suppresses the harmonic vibrations of the band in question. An equivalent in effect Arrangement according to the state The technology requires two separate filters in the radio, one of which one is a bandstop filter and the other is a low pass filter. A separate Selects switch arrangement one of the filters to use in a certain time. disadvantage of this invention the need for a space for separate filters and the suppression of the high-frequency signal as it passes through the switch arrangement.

The invention proposes a radio frequency filter that by means of an electrical signal from a bandstop into one low pass can be converted. The arrangement according to the invention can also advantageously Filters are assigned on different types of resonators based. The invention also results in a convertible filter less Size and results few unwanted Oppressions. The filter according to the invention can be made using a relatively small number of components will be realized.

The advantageous effects of the invention will be achieved with a filter arrangement in the transmission line resonators are switched as bandstops, as well as a circuit as a range for a certain control signal is included that a certain Part for any transmission line resonator with a desired one fixed potential.

According to the invention, a radio frequency filter proposed as defined in claim 1.

The invention is based on the knowledge that a transmission line resonator can be blocked in a bandstop filter by a selected Point of the resonator is connected to a constant potential which is preferably a basic potential. Such a switched Resonator does not substantially suppress a signal from it Frequency in the range of the stop band of the not switched accordingly Resonator compound is. However, the arrangement suppresses the harmonics of the frequency band in question, regardless of whether the resonators are switched accordingly (shunted) or not.

The practical implementation of the invention depends on to a certain extent depending on the technology used. The circuit that responds to a control signal in that a certain point of the resonator with a constant potential is known. In the case of wound resonators, the connection is preferably effected in the form of a tap which includes a leader the one in a selected one Point is soldered to a wound cylindrical coil conductor. Connection methods, which are applicable to other resonator designs will be described later.

The switch in the control circuit according to the invention is a known electrically controlled switch, such as a PIN diode or a transistor is.

The invention is described in detail under Reference to the advantageous embodiments given as examples and with reference to the accompanying drawings, in which

1 schematically shows the principle of the invention,

2 Figure 3 shows a circuit diagram of the application of the invention to a filter associated with a filter with helically wound resonators;

3a - 3d the measured frequency ranges of the filter according to 2 in different cases and

4 shows the application of the invention to an electrically non-conductive filter.

The same components are in all figures marked with the same reference numerals.

1 shows a filter that has two transmission line resonators 2 and 3 having. The invention does not limit the number of circuits of the filters, ie the number of resonators in them, but this patent application describes in particular filters with two resonators because one filter should be of narrow construction. The filter shown has an input connection 4 and an output port 5 , The block 6 includes matching means and other switching means which are designed to adjust the input and output impedances of the filter to correspond to desired values and which together with the resonators 2 and 4 give a band-stop frequency range unless the range is affected in any other way. One skilled in the art is familiar with the procedures for training through the block 6 shown circuits familiar.

According to the invention, the filter closes 1 also switches 7 and 8th a, both of which are arranged between a transmission conductor resonator and the ground potential. The operation of the switches is controlled by a signal that is connected to the control signal connection 9 arrives. In the illustrated embodiment, the switches each take one of two switch positions and they operate in phase, ie a certain first value of the control signal causes both switches to be open and a certain second value of the control signal causes both switches to be closed. If both switches are closed, the switches change the electrical characteristics of the resonators 2 and 3 clearly because of the grounding points 2a . 3a both resonators pretty close to the point 2 B respectively. 3b are in which the respective resonator to the block 8th is connected to implement the band lock function.

2 shows a circuit diagram of a filter 1 , which has two wound resonators 2 and 3 includes. Between the input port 4 and the first resonator winding 2 and an input port 4 and the first resonator winding 2 over the tap 2 B there is a galvanic connection. Accordingly, there is a galvanic connection between the output connection 5 and the second resonator winding 3 via a tap 3b Kapatzitäten 6a and 6b and the transmission lines, which are the connections between the input and output terminals 4 . 5 and the resonators 2 . 3 correspond to the block 6 in 1 ,

According to one aspect of the invention, this includes in 2 Filter shown a circuit with two PIN diodes D7 and D8, capacitances C7 and C8, resistors R7 and R8. The cathodes of the two PIN diodes are each with a wound resonator in a special additional tap point 2a and 3a connected. A capacitance C7 is connected between the anode of the PIN diode D7 and the basic potential and a capacitance C8 is additionally switched on between the anode of the PIN diode D8 and the basic potential; there is a connection from the anodes of both PIN diodes via resistor R7, R8 and the control signal connection 9 , In the embodiment shown, the distance between the tapping point corresponds 2 B . 3b and the additional starting point 2a . 3a about one winding revolution of both wound resonators. However, the distance can also be larger or smaller than such a winding revolution.

In connection with the investigations that led to the invention, a wound resonator was developed according to 2 manufactured, whose frequency range with different values of the voltage of a voltage signal a control signal connection 9 was fed. Was the control signal zero, or was the control signal connector 9 essentially basic potential, the PIN diodes D7 and D8 were biased opposite to each other, which indicates the open switch position of the switches 7 and 8th in 1 equivalent. Because the frequency range of the filter, described as a passage from the input port 4 to the output connection 5 according to 3a and 3b , Curve 10 , indicates the transmission coefficient on a scale described when the frequency changes from 370 MHz to 400 MHz. The curve shows, in the form of a drop in the curve, a stop zone whose central frequency is approximately 392 MHz. 3b explained using a curve 11 determining a transmission coefficient at higher frequencies. 3b shows at the first harmonic (784 MHz) the stop band center frequency that the suppression is above 30 dB and at the other harmonics up to 2 GHz, the suppression is above 50 dB.

When a positive voltage signal to the control signal terminal 9 in a filter 9 according to 2 is supplied, the PIN diodes D7 and D8 are biased forward. Then, as far as it exists relates to a radio frequency signal, a connection from the additional tapping points 2a and 3a to the basic potential. Capacitors C7 and C8 isolate the DC voltage signal that comes to the control signal connection from the base potential and resistors R7 and R8 from the base potential and resistors R7 and R8 prevent the radio frequency signal with the control signal connection 9 to be connected 3c and 3d show the passage of the filter at fundamental frequency ( 3c , Curve 12 ) and harmonics ( 3d , Curve 13 ) when a positive voltage signal comes to the control signal terminal. Curve 12 shows that the passage of the filter is already flat and less than –1 dB over the entire measured range. Curve 13 in 3d shows, however, that the suppression of harmonic frequencies (these are the "harmonics") is essentially identical 3b is where there is no voltage signal at the control signal input.

The invention is not limited to devices with wound resonators. 4 shows an electrically non-conductive block 14 , which is essentially a right-angled prism, which is formed by means of four side faces which are parallel in pairs and which lie perpendicular to one another and are formed by two end faces. Two cylindrical holes 15 and 16 extend from the one end surface to the other as shown in the drawing, and the inner surfaces of the holes are coated with electrically conductive material. Both holes together with the partial coating of the outer surfaces of the block thus form a transmission line resonator. The formation of a filter using an electrically non-conductive resonator block according to 4 is state of the art. block 14 does not necessarily have to be in one piece, it can be composed of several parts which are assigned to one another. For example, each resonator can be formed using its own base block part. In addition, the block does not necessarily have to be a rectangular prism.

For connection to the resonators, the upper end surface in the drawing, which is otherwise uncoated, has connection areas 17 and 18 which are an electrically conductive coating. According to the invention, there are also connection areas on one side of the electrical block 19 and 20 trained who respond to a specific control signal. A capacitive connection from the transmission line resonators 15 and 18 out and over the connection areas 19 and 20 cause the frequency response of the filter to the basic potential; in connection with this are used the resonators to which a circuit can be connected. As a result of a certain control signal according to the invention, there are connection areas on one side surface of the electrically non-conductive block 19 and 20 trained to which a circuit can be connected to the connection areas 19 and 20 justify as a result of a certain control signal. A capacitive connection from the transmission line resonators 19 and 20 off to the basic potential causes the frequency response of the filter; in conjunction, the resonators are effective to according to 3a to 3d to effect the change described above. The the switch 7 and 8th and a control signal connector 9 including circuit is only shown schematically, but its implementation in practice using appropriate assemblies associated with solder paths (not shown) on the block area is known in the art.

It is known capacitive and galvanic connections as well as other types of resonators, such as strip conductors and coaxial resonators, so that the basic coupling according to the invention can be easily assigned to them. The location of the arrangement of the base point in the resonator and the rotation used in the basic coupling can be experimental can be determined by experimentally determining such as, for example of the desired Impedance striking the filter and the desired total suppression of the Signals affected become.

Measurement results for a filter were presented above, which has a normal working frequency of around 385-392 MHz. The invention however, it is not limited to filters of a particular frequency range. she can all devices for processing radio frequency signals assigned with advantage, where the filters should be small and whose frequency range must be electrically variable. The invention includes except the resonators a few other components, so their manufacturing costs are low and there are good conditions for mass production are. Thanks to the small number of components goes with the invention the unwanted suppression in a radio frequency signal only to a very small extent.

Claims (9)

Radio frequency filter, which includes - an input connection and an output connection, - a first transmission line resonator in the signal path and a second transmission line resonator in the signal path and - a control signal connection for an external control signal and with a frequency response of the type of a bandstopper within a certain frequency range, characterized in that for exclusion the bandstop filter from the mentioned frequency range - the first transmission line resonator ( 2 ) a first connection point ( 2a ; 19 ) with a first switch ( 7 ) which is arranged to to connect the first connection point to a reference potential, depending on the external control signal mentioned, and - the second transmission line resonator ( 3 ) a second connection point ( 3a ; 20 ) with a second switch ( 8th ) is connected, which is arranged to connect the second connection point to a reference potential as a function of the external control signal mentioned. Radio frequency filter according to claim 1, characterized in that the reference potential mentioned is the basic potential. Radio frequency filter according to claim 1, characterized in that said transmission line resonators ( 2 . 3 ) are wound resonators. Radio frequency filter according to claim 3, characterized in that said first transmission conductor resonator ( 2 ) a first stage ( 2 B ) for connection to the latch of the filter and that said first stage contains a first additional stage ( 2a ) and that the second transmission conductor resonator ( 3 ) a second stage ( 3b ) for connection to the catch of the filter and that said second stage contains a second additional stage ( 3a ) is. Radio frequency filter according to claim 4, characterized in that in both transmission line resonators the distance from the stage ( 2 B . 3b ) to the additional level ( 2a . 3a ) is essentially a winding turn. Radio frequency filter according to claim 1, characterized in that the transmission conductor resonators ( 2 . 3 ) are electrically non-conductive resonators. Radio frequency filter according to claim 1, characterized in that said transmission line resonators ( 2 . 3 ) Are coaxial resonators. Radio frequency filter according to claim 1, characterized in that said transmission line resonators ( 2 . 3 ) Are stripline resonators. Radio frequency filter according to claim 1, characterized in that said first and said second switches are the same, both contain a PIN diode (D7, D8), the cathode of which is connected to a transmission line resonator and the anode of which is via a capacitive element (C7, C8 ) is connected to said reference potential, and that a resistance element (R7, R8) between the anode of said PIN diode and said control signal connection ( 9 ) is switched on.